DE2363274C3 - Display device for measuring the relative displacement of a spring-loaded feeler element - Google Patents

Description

The invention relates to a display device for measuring the relative displacement of a spring-loaded Probe member with respect to a surface to be measured, one end of the probe member in contact is held with the surface to be measured and in accordance with the displacement of the to measuring surface is axially movable.

One known type of indicator, such as the Rockwell hardness tester, uses a dial rotated to set a main pointer to a graduation that serves as a reference point when a feeler element, which engages in a probe shaft, pressed against the surface to be measured by a spring will. This practice has the problem that the measurement process becomes extremely complex.

Other instruments use an auxiliary pointer Pa ' (Fig. 6), which has a lower sensitivity than the main pointer P and is intended to help determine the reference position of the main pointer. In this case, however, the auxiliary pointer is relatively short so that it does not hit the shaft of the main pointer when the auxiliary pointer moves on the dial, which has the disadvantage that the auxiliary pointer cannot be precisely set to graduation marks.

When measuring the axial deviation, e.g. B. a control curve, has the same defect as with the Rockwell hardness testers shown as it is difficult to adjust the pointer to the reference position while the feeler member is to be kept in contact with the surface of the control cam.

The invention is therefore based on the object of a display device for measuring the relative displacement to provide a spring-loaded feeler element with respect to a surface to be measured, the simple is under construction and allows precise reading of measured values.

To solve this problem, it is proposed according to the invention that the feeler element be provided with an auxiliary pointer bearing pinion is in engagement, a gear concentric via a ίο spring-loaded friction clutch is assigned, which is in engagement with a second pinion carrying the main pointer without play, and that the gear wheel has stops through which the pivot range corresponding to a reference position of the gear wheel and thus that of the main pointer is limited by means of a »stop link.

What is achieved is that the main pointer can be adjusted to the reference graduation, in accordance with the starting position of the surface to be measured.

The display device according to the invention for measuring a relative displacement cause! very easy that Main pointer to be set to the reference graduation and / was in agreement with the initial position the surface to be measured. In addition, with the help of the * sufficiently long auxiliary pointer. which is curved so as not to come into contact with the shaft of the main pointer, the precision the setting of the reference graduation is remarkably high.

It is also useful to ensure that the auxiliary pointer is laterally below the pointer shaft of the The main pointer is mounted and curved in this way. that it is adjustable in the division range in which the main pointer is in its one end position without touching the pointer shaft of the main pointer. Achieved is thereby that the precision of the setting of the reference graduation is remarkably high.

If the feeler element of the specified display device is brought into contact with a lever, which is below Effect of the test tip of a Rockwell hardness tester, then the display accuracy of Rockwell hardness testers significantly improved.

The invention is explained below with reference to an exemplary embodiment shown in the drawings. It shows

F i g. 1 is a rear view of a display device for measuring the relative displacement of a spring-loaded Tactile element, part of which has been removed in order to make the interior of the device visible,

FIG. 2 shows a cross section along the line II II in FIG. 1.

F i g. 3 is a front view of the display device according to the invention.

Fig. 4 is a partial rear view of a modification part of the display device,

F1 g 5 the arrangement of the display device in cooperation with a Rockwell hardness tester,

F i g. 6 is a front view of a known display device.

As shown in FIGS. 1 to 3, a feeler element 1 is guided in a display device H and is arranged, influenced by a spring 2, so that this feeler element is axially movable, one end remaining in contact with a surface S to be measured, the relative displacement of which is to be measured.

In a designed as a rack section 3 of the feeler member I engages a pinion 4, which is when

Moving the feeler member rotates. A sector gear 5 is arranged concentrically to the pinion 4. A second pinion 6, which is located in the center of the display device H , meshes with the larger sector pinion gear 5 and a main pointer is fixed on a pointer blade O, this pinion 6.

As shown in FIG. 2, the sector gear 5 and the first pinion 4 are connected to one another, n. And zv, ar via a spring-loaded friction clutch 7, which consists of a pressure party Ta and a ring Tb . If the first pinion 4 is driven via the toothed section 3 when moving the feeler element, ί, then the pinion 4 and the sector gear 5 rotate as a unit.

The sector gear 5 is assigned a slope 8 (FIGS. 1 and 2), so that when the sector gear 5 rotates clockwise by moving the feeler element 1, as indicated by an arrow in FIG. 1 illustrates that one end of the sector gear 5 designed as a stop 5a touches the stop member 8 in order to stop the rotation of the sector gear 5 when the main pointer P points to the graduation (?.

When the sector gear 5 is stopped in this way, the ring Tb of the friction clutch 7 slips against the pinion 4 (FIG. 2), ie the main pointer P remains on the graduation ζ), even if the feeler element 1 always is still shifting in the same direction.

In this display device, an auxiliary / Eig ° r Pa is also provided, which is carried by the pinion 4 and rotates with it and is fixed on a shaft Ch. This auxiliary pointer Pa continues to rotate with low sensitivity, even if the main pointer P stops. If the auxiliary pointer Pa comes into a predetermined division range Qi. Qi, then the feeler element 1 is lifted from the surface S to be measured.

The predetermined graduation range Qi, Qi is opposite the shaft Ch of the auxiliary pointer Pa , which is laterally below the pointer shaft Oi of the main pointer P, and the auxiliary pointer Pa is made long enough to facilitate adjustment to the graduation If such a long auxiliary pointer Pa were straight if it were set, it would come into line with the wave Oi of the main pointer, so it is curved (FIG. 3) so that the pointer can be adjusted to the predetermined sub-area Qi, Q2 without that the shaft of the main pointer Oi is touched.

If the surface S to be measured recedes, the feeler element 1 follows it according to the action of the force of the spring 2.If the pinion 4 rotates counterclockwise because the feeler element is moved downwards via the rack 3, the sector gear 5 rotates also backwards, via the friction clutch 7, the displacement of the surface 5 to be measured being measured by the amount (! er rotation of the main pointer P with respect to the graduation. This pivoting range is limited by the fact that the other end serving as stop 5b (Fig. 1) of the sector gear 5 contacts the stop member 8. deviates the feeler member 1 under the action of the spring 2 back, so it follows the retreating, surface to be measured, so it is moved to the outside. Then, the provided with the stopper 5b other End of the sector gear 5 stopped by the S'oppelement 8, so that the main pointer P also stops, and, since the surface to be measured is still falling, the ring Tb and the Ri slide tzel 4 on top of each other, ie only the auxiliary pointer Pa continues to rotate. In addition, a further stop member (not shown) is provided in order to limit the path of the feeler member within the actual display device H.

With the second pinion 6 of the main hand P , an auxiliary gear 11 influenced by a fine spiral spring 10 is engaged to prevent backlash in the gear mechanism.

One end of the spring 2 engages a transverse arm 12 and the other end engages a fixed point 13 of the display device H. In order to intercept the pressure of the compression spring Ta , a stop ring 14 is provided behind the sector gear 5. Screws 15 fix the stop member 8 on the display device H.

Bearings 16a and 16Z) are used to store or guide the feeler element 1.

Fig. 4 shows a modification of the above sector gear. This is designed here as a normal gearwheel 5 ', on which stops 5a' and 5b 'are fixed, which are in contact with the stop member 8

come. In this case as well, the same operation and result can be obtained as with the previously described embodiment.

F 1 g. 5 shows the application of the display device according to the invention to a Rockwell hardness tester. Around

Applying standardized loads to a specimen 17 by means of a test probe 18 is carried out with the aid of a rod 19 Table 20 raised, whereby a test probe shaft 21 is pushed upwards, which is a standardized Compresses the load spring so as to allow the use of standardized loads.

A transmission lever 24 is pivoted via a contact member 23 fixed on the test probe shaft 21, whereby the feeler member 1 of the display device H of the invention, which is in contact with the to be measured

send surface S comes, is moved upwards.

As a result of the process explained above, the main pointer P of the display device stops at the graduation O while the auxiliary pointer Pa continues to rotate. By ending the stroke of the rod 19, when the auxiliary pointer Pa comes into the predetermined graduation range Qi, Qi , it is set where it corresponds to the standardized load.

The application of test loads to Rockwell hardness testers can be achieved if a control rod

ge 25 is provided, on which a load lever 26 is supported, which transmits the load of a weight 27 to the test probe shaft 21 via a load shaft 28 with a point on one side and a guide cylinder 29. The load lever is mounted at 30 (Fig. 5). When the control rod 25 is lowered, the main pointer P indicates the measured value in accordance with the depth of the indentation of the probe tip 18 into the sample 17.

A nut 31 sets one end of a leaf spring 34 which resiliently influences the test probe shaft 21;

the other end is device-proof. The transmission lever 24 is mounted at 32; 33 is a stop link that the lowering of the probe shaft 21 is limited.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Display device for measuring the relative displacement of a spring-loaded probe member with respect to a surface to be measured, wherein one end of the probe member is held in contact with the surface to be measured and is axially movable in accordance with the displacement of the surface to be measured, characterized that the feeler element (1) is in engagement with a pinion (4) carrying a pinion (4) which carries a spring-loaded friction clutch (7) and is concentrically associated with a gear (5, 5 ') which is in engagement with one of the backlash-free Main pointer (P) bearing the second pinion (6) is, and that the gear (5.5 ') has stops (5a, 56, 5a', 5tf) through which the pivoting range of the gear (5.5 ') corresponding to a reference position and so that of the master (P) is limited by means of a device-fixed stop member (8). 2 display device according to claim 1, characterized in that the auxiliary pointer (Pa) is mounted laterally below the pointer shaft (Οι) of the main pointer ( P) and is curved in such a way that it is adjustable in the graduation area (Q. ^, in which the main / eiger (P) is in one of its end positions (Q) without touching the pointer shaft (O \) of the main pointer (P) / u. 3. Display device according to claim 1 or 2, characterized in that the feeler element (1) mil one Lever (24) is in operative connection, which is under the action of the test probe (18) of a Rockwell hardness tester stands.